#include "cube.hh" ///////////////////////// cryptography ///////////////////////////////// /* Based off the reference implementation of Tiger, a cryptographically * secure 192 bit hash function by Ross Anderson and Eli Biham. More info at: * http://www.cs.technion.ac.il/~biham/Reports/Tiger/ */ #define TIGER_PASSES 3 namespace tiger { typedef unsigned long long int chunk; union hashval { uchar bytes[3*8]; chunk chunks[3]; }; chunk sboxes[4*256]; void compress(const chunk *str, chunk state[3]) { chunk a, b, c; chunk aa, bb, cc; chunk x0, x1, x2, x3, x4, x5, x6, x7; a = state[0]; b = state[1]; c = state[2]; x0=str[0]; x1=str[1]; x2=str[2]; x3=str[3]; x4=str[4]; x5=str[5]; x6=str[6]; x7=str[7]; aa = a; bb = b; cc = c; loop(pass_no, TIGER_PASSES) { if(pass_no) { x0 -= x7 ^ 0xA5A5A5A5A5A5A5A5ULL; x1 ^= x0; x2 += x1; x3 -= x2 ^ ((~x1)<<19); x4 ^= x3; x5 += x4; x6 -= x5 ^ ((~x4)>>23); x7 ^= x6; x0 += x7; x1 -= x0 ^ ((~x7)<<19); x2 ^= x1; x3 += x2; x4 -= x3 ^ ((~x2)>>23); x5 ^= x4; x6 += x5; x7 -= x6 ^ 0x0123456789ABCDEFULL; } #define sb1 (sboxes) #define sb2 (sboxes+256) #define sb3 (sboxes+256*2) #define sb4 (sboxes+256*3) #define round(a, b, c, x) \ c ^= x; \ a -= sb1[((c)>>(0*8))&0xFF] ^ sb2[((c)>>(2*8))&0xFF] ^ \ sb3[((c)>>(4*8))&0xFF] ^ sb4[((c)>>(6*8))&0xFF] ; \ b += sb4[((c)>>(1*8))&0xFF] ^ sb3[((c)>>(3*8))&0xFF] ^ \ sb2[((c)>>(5*8))&0xFF] ^ sb1[((c)>>(7*8))&0xFF] ; \ b *= mul; uint mul = !pass_no ? 5 : (pass_no==1 ? 7 : 9); round(a, b, c, x0) round(b, c, a, x1) round(c, a, b, x2) round(a, b, c, x3) round(b, c, a, x4) round(c, a, b, x5) round(a, b, c, x6) round(b, c, a, x7) chunk tmp = a; a = c; c = b; b = tmp; } a ^= aa; b -= bb; c += cc; state[0] = a; state[1] = b; state[2] = c; } void gensboxes() { const char *str = "Tiger - A Fast New Hash Function, by Ross Anderson and Eli Biham"; chunk state[3] = { 0x0123456789ABCDEFULL, 0xFEDCBA9876543210ULL, 0xF096A5B4C3B2E187ULL }; uchar temp[64]; if(!islittleendian()) loopj(64) temp[j^7] = str[j]; else loopj(64) temp[j] = str[j]; loopi(1024) loop(col, 8) ((uchar *)&sboxes[i])[col] = i&0xFF; int abc = 2; loop(pass, 5) loopi(256) for(int sb = 0; sb < 1024; sb += 256) { abc++; if(abc >= 3) { abc = 0; compress((chunk *)temp, state); } loop(col, 8) { uchar val = ((uchar *)&sboxes[sb+i])[col]; ((uchar *)&sboxes[sb+i])[col] = ((uchar *)&sboxes[sb + ((uchar *)&state[abc])[col]])[col]; ((uchar *)&sboxes[sb + ((uchar *)&state[abc])[col]])[col] = val; } } } void hash(const uchar *str, int length, hashval &val) { static bool init = false; if(!init) { gensboxes(); init = true; } uchar temp[64]; val.chunks[0] = 0x0123456789ABCDEFULL; val.chunks[1] = 0xFEDCBA9876543210ULL; val.chunks[2] = 0xF096A5B4C3B2E187ULL; int i = length; for(; i >= 64; i -= 64, str += 64) { if(!islittleendian()) { loopj(64) temp[j^7] = str[j]; compress((chunk *)temp, val.chunks); } else compress((chunk *)str, val.chunks); } int j; if(!islittleendian()) { for(j = 0; j < i; j++) temp[j^7] = str[j]; temp[j^7] = 0x01; while(++j&7) temp[j^7] = 0; } else { for(j = 0; j < i; j++) temp[j] = str[j]; temp[j] = 0x01; while(++j&7) temp[j] = 0; } if(j > 56) { while(j < 64) temp[j++] = 0; compress((chunk *)temp, val.chunks); j = 0; } while(j < 56) temp[j++] = 0; *(chunk *)(temp+56) = (chunk)length<<3; compress((chunk *)temp, val.chunks); if(!islittleendian()) { loopk(3) { uchar *c = &val.bytes[k*sizeof(chunk)]; loopl(sizeof(chunk)/2) swap(c[l], c[sizeof(chunk)-1-l]); } } } } /* Elliptic curve cryptography based on NIST DSS prime curves. */ #define BI_DIGIT_BITS 16 #define BI_DIGIT_MASK ((1< struct bigint { typedef ushort digit; typedef uint dbldigit; int len; digit digits[BI_DIGITS]; bigint() {} bigint(digit n) { if(n) { len = 1; digits[0] = n; } else len = 0; } bigint(const char *s) { parse(s); } template bigint(const bigint &y) { *this = y; } static int parsedigits(ushort *digits, int maxlen, const char *s) { int slen = 0; while(isxdigit(s[slen])) slen++; int len = (slen+2*sizeof(ushort)-1)/(2*sizeof(ushort)); if(len>maxlen) return 0; memset(digits, 0, len*sizeof(ushort)); loopi(slen) { int c = s[slen-i-1]; if(isalpha(c)) c = toupper(c) - 'A' + 10; else if(isdigit(c)) c -= '0'; else return 0; digits[i/(2*sizeof(ushort))] |= c<<(4*(i%(2*sizeof(ushort)))); } return len; } void parse(const char *s) { len = parsedigits(digits, BI_DIGITS, s); shrink(); } void zero() { len = 0; } void print(stream *out) const { vector buf; printdigits(buf); out->write(buf.getbuf(), buf.length()); } void printdigits(vector &buf) const { loopi(len) { digit d = digits[len-i-1]; loopj(BI_DIGIT_BITS/4) { uint shift = BI_DIGIT_BITS - (j+1)*4; int val = (d >> shift) & 0xF; if(val < 10) buf.add('0' + val); else buf.add('a' + val - 10); } } } template bigint &operator=(const bigint &y) { len = y.len; memcpy(digits, y.digits, len*sizeof(digit)); return *this; } bool iszero() const { return !len; } bool isone() const { return len==1 && digits[0]==1; } int numbits() const { if(!len) return 0; int bits = len*BI_DIGIT_BITS; digit last = digits[len-1], mask = 1<<(BI_DIGIT_BITS-1); while(mask) { if(last&mask) return bits; bits--; mask >>= 1; } return 0; } bool hasbit(int n) const { return n/BI_DIGIT_BITS < len && ((digits[n/BI_DIGIT_BITS]>>(n%BI_DIGIT_BITS))&1); } bool morebits(int n) const { return len > n/BI_DIGIT_BITS; } template bigint &add(const bigint &x, const bigint &y) { dbldigit carry = 0; int maxlen = max(x.len, y.len), i; for(i = 0; i < y.len || carry; i++) { carry += (i < x.len ? (dbldigit)x.digits[i] : 0) + (i < y.len ? (dbldigit)y.digits[i] : 0); digits[i] = (digit)carry; carry >>= BI_DIGIT_BITS; } if(i < x.len && this != &x) memcpy(&digits[i], &x.digits[i], (x.len - i)*sizeof(digit)); len = max(i, maxlen); return *this; } template bigint &add(const bigint &y) { return add(*this, y); } template bigint &sub(const bigint &x, const bigint &y) { ASSERT(x >= y); dbldigit borrow = 0; int i; for(i = 0; i < y.len || borrow; i++) { borrow = (1<>BI_DIGIT_BITS)^1; } if(i < x.len && this != &x) memcpy(&digits[i], &x.digits[i], (x.len - i)*sizeof(digit)); len = x.len; shrink(); return *this; } template bigint &sub(const bigint &y) { return sub(*this, y); } void shrink() { while(len > 0 && !digits[len-1]) len--; } void shrinkdigits(int n) { len = n; shrink(); } void shrinkbits(int n) { shrinkdigits(n/BI_DIGIT_BITS); } template void copyshrinkdigits(const bigint &y, int n) { len = clamp(y.len, 0, n); memcpy(digits, y.digits, len*sizeof(digit)); shrink(); } template void copyshrinkbits(const bigint &y, int n) { copyshrinkdigits(y, n/BI_DIGIT_BITS); } template bigint &mul(const bigint &x, const bigint &y) { if(!x.len || !y.len) { len = 0; return *this; } memset(digits, 0, y.len*sizeof(digit)); loopi(x.len) { dbldigit carry = 0; loopj(y.len) { carry += (dbldigit)x.digits[i] * (dbldigit)y.digits[j] + (dbldigit)digits[i+j]; digits[i+j] = (digit)carry; carry >>= BI_DIGIT_BITS; } digits[i+y.len] = carry; } len = x.len + y.len; shrink(); return *this; } bigint &rshift(int n) { assert(len <= BI_DIGITS); if(!len || n<=0) return *this; if(n >= len*BI_DIGIT_BITS) { len = 0; return *this; } int dig = (n-1)/BI_DIGIT_BITS; n = ((n-1) % BI_DIGIT_BITS)+1; digit carry = digit(digits[dig]>>n); for(int i = dig+1; i < len; i++) { digit tmp = digits[i]; digits[i-dig-1] = digit((tmp<<(BI_DIGIT_BITS-n)) | carry); carry = digit(tmp>>n); } digits[len-dig-1] = carry; len -= dig + (n/BI_DIGIT_BITS); shrink(); return *this; } bigint &lshift(int n) { if(!len || n<=0) return *this; int dig = n/BI_DIGIT_BITS; n %= BI_DIGIT_BITS; digit carry = 0; loopirev(len) { digit tmp = digits[i]; digits[i+dig] = digit((tmp<>(BI_DIGIT_BITS-n)); } len += dig; if(carry) digits[len++] = carry; if(dig) memset(digits, 0, dig*sizeof(digit)); return *this; } void zerodigits(int i, int n) { memset(&digits[i], 0, n*sizeof(digit)); } void zerobits(int i, int n) { zerodigits(i/BI_DIGIT_BITS, n/BI_DIGIT_BITS); } template void copydigits(int to, const bigint &y, int from, int n) { int avail = clamp(y.len-from, 0, n); memcpy(&digits[to], &y.digits[from], avail*sizeof(digit)); if(avail < n) memset(&digits[to+avail], 0, (n-avail)*sizeof(digit)); } template void copybits(int to, const bigint &y, int from, int n) { copydigits(to/BI_DIGIT_BITS, y, from/BI_DIGIT_BITS, n/BI_DIGIT_BITS); } void dupdigits(int to, int from, int n) { memcpy(&digits[to], &digits[from], n*sizeof(digit)); } void dupbits(int to, int from, int n) { dupdigits(to/BI_DIGIT_BITS, from/BI_DIGIT_BITS, n/BI_DIGIT_BITS); } template bool operator==(const bigint &y) const { if(len!=y.len) return false; loopirev(len) if(digits[i]!=y.digits[i]) return false; return true; } template bool operator!=(const bigint &y) const { return !(*this==y); } template bool operator<(const bigint &y) const { if(leny.len) return false; loopirev(len) { if(digits[i]y.digits[i]) return false; } return false; } template bool operator>(const bigint &y) const { return y<*this; } template bool operator<=(const bigint &y) const { return !(y<*this); } template bool operator>=(const bigint &y) const { return !(*this gfint; /* NIST prime Galois fields. * Currently only supports NIST P-192, where P=2^192-2^64-1, and P-256, where P=2^256-2^224+2^192+2^96-1. */ struct gfield : gfint { static const gfield P; gfield() {} gfield(digit n) : gfint(n) {} gfield(const char *s) : gfint(s) {} template gfield(const bigint &y) : gfint(y) {} template gfield &operator=(const bigint &y) { gfint::operator=(y); return *this; } template gfield &add(const bigint &x, const bigint &y) { gfint::add(x, y); if(*this >= P) gfint::sub(*this, P); return *this; } template gfield &add(const bigint &y) { return add(*this, y); } template gfield &mul2(const bigint &x) { return add(x, x); } gfield &mul2() { return mul2(*this); } gfield &div2() { if(hasbit(0)) gfint::add(*this, P); rshift(1); return *this; } template gfield &sub(const bigint &x, const bigint &y) { if(x < y) { gfint tmp; /* necessary if this==&y, using this instead would clobber y */ tmp.add(x, P); gfint::sub(tmp, y); } else gfint::sub(x, y); return *this; } template gfield &sub(const bigint &y) { return sub(*this, y); } template gfield &neg(const bigint &x) { gfint::sub(P, x); return *this; } gfield &neg() { return neg(*this); } template gfield &square(const bigint &x) { return mul(x, x); } gfield &square() { return square(*this); } template gfield &mul(const bigint &x, const bigint &y) { bigint result; result.mul(x, y); reduce(result); return *this; } template gfield &mul(const bigint &y) { return mul(*this, y); } template void reduce(const bigint &result) { #if GF_BITS==192 // B = T + S1 + S2 + S3 mod p copyshrinkdigits(result, GF_DIGITS); // T if(result.morebits(192)) { gfield s; s.copybits(0, result, 192, 64); s.dupbits(64, 0, 64); s.shrinkbits(128); add(s); // S1 if(result.morebits(256)) { s.zerobits(0, 64); s.copybits(64, result, 256, 64); s.dupbits(128, 64, 64); s.shrinkdigits(GF_DIGITS); add(s); // S2 if(result.morebits(320)) { s.copybits(0, result, 320, 64); s.dupbits(64, 0, 64); s.dupbits(128, 0, 64); s.shrinkdigits(GF_DIGITS); add(s); // S3 } } } else if(*this >= P) gfint::sub(*this, P); #elif GF_BITS==256 // B = T + 2*S1 + 2*S2 + S3 + S4 - D1 - D2 - D3 - D4 mod p copyshrinkdigits(result, GF_DIGITS); // T if(result.morebits(256)) { gfield s; if(result.morebits(352)) { s.zerobits(0, 96); s.copybits(96, result, 352, 160); s.shrinkdigits(GF_DIGITS); add(s); add(s); // S1 if(result.morebits(384)) { //s.zerobits(0, 96); s.copybits(96, result, 384, 128); s.shrinkbits(224); add(s); add(s); // S2 } } s.copybits(0, result, 256, 96); s.zerobits(96, 96); s.copybits(192, result, 448, 64); s.shrinkdigits(GF_DIGITS); add(s); // S3 s.copybits(0, result, 288, 96); s.copybits(96, result, 416, 96); s.dupbits(192, 96, 32); s.copybits(224, result, 256, 32); s.shrinkdigits(GF_DIGITS); add(s); // S4 s.copybits(0, result, 352, 96); s.zerobits(96, 96); s.copybits(192, result, 256, 32); s.copybits(224, result, 320, 32); s.shrinkdigits(GF_DIGITS); sub(s); // D1 s.copybits(0, result, 384, 128); //s.zerobits(128, 64); s.copybits(192, result, 288, 32); s.copybits(224, result, 352, 32); s.shrinkdigits(GF_DIGITS); sub(s); // D2 s.copybits(0, result, 416, 96); s.copybits(96, result, 256, 96); s.zerobits(192, 32); s.copybits(224, result, 384, 32); s.shrinkdigits(GF_DIGITS); sub(s); // D3 s.copybits(0, result, 448, 64); s.zerobits(64, 32); s.copybits(96, result, 288, 96); //s.zerobits(192, 32); s.copybits(224, result, 416, 32); s.shrinkdigits(GF_DIGITS); sub(s); // D4 } else if(*this >= P) gfint::sub(*this, P); #else #error Unsupported GF #endif } template gfield &pow(const bigint &x, const bigint &y) { gfield a(x); if(y.hasbit(0)) *this = a; else { len = 1; digits[0] = 1; if(!y.len) return *this; } for(int i = 1, j = y.numbits(); i < j; i++) { a.square(); if(y.hasbit(i)) mul(a); } return *this; } template gfield &pow(const bigint &y) { return pow(*this, y); } bool invert(const gfield &x) { if(!x.len) return false; gfint u(x), v(P), A((gfint::digit)1), C((gfint::digit)0); while(!u.iszero()) { int ushift = 0, ashift = 0; while(!u.hasbit(ushift)) { ushift++; if(A.hasbit(ashift)) { if(ashift) { A.rshift(ashift); ashift = 0; } A.add(P); } ashift++; } if(ushift) u.rshift(ushift); if(ashift) A.rshift(ashift); int vshift = 0, cshift = 0; while(!v.hasbit(vshift)) { vshift++; if(C.hasbit(cshift)) { if(cshift) { C.rshift(cshift); cshift = 0; } C.add(P); } cshift++; } if(vshift) v.rshift(vshift); if(cshift) C.rshift(cshift); if(u >= v) { u.sub(v); if(A < C) A.add(P); A.sub(C); } else { v.sub(v, u); if(C < A) C.add(P); C.sub(A); } } if(C >= P) gfint::sub(C, P); else { len = C.len; memcpy(digits, C.digits, len*sizeof(digit)); } ASSERT(*this < P); return true; } void invert() { invert(*this); } template static int legendre(const bigint &x) { static const gfint Psub1div2(gfint(P).sub(bigint<1>(1)).rshift(1)); gfield L; L.pow(x, Psub1div2); if(!L.len) return 0; if(L.len==1) return 1; return -1; } int legendre() const { return legendre(*this); } bool sqrt(const gfield &x) { if(!x.len) { len = 0; return true; } #if GF_BITS==224 #error Unsupported GF #else ASSERT((P.digits[0]%4)==3); static const gfint Padd1div4(gfint(P).add(bigint<1>(1)).rshift(2)); switch(legendre(x)) { case 0: len = 0; return true; case -1: return false; default: pow(x, Padd1div4); return true; } #endif } bool sqrt() { return sqrt(*this); } }; struct ecjacobian { static const gfield B; static const ecjacobian base; static const ecjacobian origin; gfield x, y, z; ecjacobian() {} ecjacobian(const gfield &x, const gfield &y) : x(x), y(y), z(bigint<1>(1)) {} ecjacobian(const gfield &x, const gfield &y, const gfield &z) : x(x), y(y), z(z) {} void mul2() { if(z.iszero()) return; else if(y.iszero()) { *this = origin; return; } gfield a, b, c, d; d.sub(x, c.square(z)); d.mul(c.add(x)); c.mul2(d).add(d); z.mul(y).add(z); a.square(y); b.mul2(a); d.mul2(x).mul(b); x.square(c).sub(d).sub(d); a.square(b).add(a); y.sub(d, x).mul(c).sub(a); } void add(const ecjacobian &q) { if(q.z.iszero()) return; else if(z.iszero()) { *this = q; return; } gfield a, b, c, d, e, f; a.square(z); b.mul(q.y, a).mul(z); a.mul(q.x); if(q.z.isone()) { c.add(x, a); d.add(y, b); a.sub(x, a); b.sub(y, b); } else { f.mul(y, e.square(q.z)).mul(q.z); e.mul(x); c.add(e, a); d.add(f, b); a.sub(e, a); b.sub(f, b); } if(a.iszero()) { if(b.iszero()) mul2(); else *this = origin; return; } if(!q.z.isone()) z.mul(q.z); z.mul(a); x.square(b).sub(f.mul(c, e.square(a))); y.sub(f, x).sub(x).mul(b).sub(e.mul(a).mul(d)).div2(); } template void mul(const ecjacobian &p, const bigint &q) { *this = origin; loopirev(q.numbits()) { mul2(); if(q.hasbit(i)) add(p); } } template void mul(const bigint &q) { ecjacobian tmp(*this); mul(tmp, q); } void normalize() { if(z.iszero() || z.isone()) return; gfield tmp; z.invert(); tmp.square(z); x.mul(tmp); y.mul(tmp).mul(z); z = bigint<1>(1); } bool calcy(bool ybit) { gfield y2, tmp; y2.square(x).mul(x).sub(tmp.add(x, x).add(x)).add(B); if(!y.sqrt(y2)) { y.zero(); return false; } if(y.hasbit(0) != ybit) y.neg(); return true; } void print(vector &buf) { normalize(); buf.add(y.hasbit(0) ? '-' : '+'); x.printdigits(buf); } void parse(const char *s) { bool ybit = *s++ == '-'; x.parse(s); calcy(ybit); z = bigint<1>(1); } }; const ecjacobian ecjacobian::origin(gfield((gfield::digit)1), gfield((gfield::digit)1), gfield((gfield::digit)0)); #if GF_BITS==192 const gfield gfield::P("fffffffffffffffffffffffffffffffeffffffffffffffff"); const gfield ecjacobian::B("64210519e59c80e70fa7e9ab72243049feb8deecc146b9b1"); const ecjacobian ecjacobian::base( gfield("188da80eb03090f67cbf20eb43a18800f4ff0afd82ff1012"), gfield("07192b95ffc8da78631011ed6b24cdd573f977a11e794811") ); #elif GF_BITS==224 const gfield gfield::P("ffffffffffffffffffffffffffffffff000000000000000000000001"); const gfield ecjacobian::B("b4050a850c04b3abf54132565044b0b7d7bfd8ba270b39432355ffb4"); const ecjacobian ecjacobian::base( gfield("b70e0cbd6bb4bf7f321390b94a03c1d356c21122343280d6115c1d21"), gfield("bd376388b5f723fb4c22dfe6cd4375a05a07476444d5819985007e34") ); #elif GF_BITS==256 const gfield gfield::P("ffffffff00000001000000000000000000000000ffffffffffffffffffffffff"); const gfield ecjacobian::B("5ac635d8aa3a93e7b3ebbd55769886bc651d06b0cc53b0f63bce3c3e27d2604b"); const ecjacobian ecjacobian::base( gfield("6b17d1f2e12c4247f8bce6e563a440f277037d812deb33a0f4a13945d898c296"), gfield("4fe342e2fe1a7f9b8ee7eb4a7c0f9e162bce33576b315ececbb6406837bf51f5") ); #elif GF_BITS==384 const gfield gfield::P("fffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffeffffffff0000000000000000ffffffff"); const gfield ecjacobian::B("b3312fa7e23ee7e4988e056be3f82d19181d9c6efe8141120314088f5013875ac656398d8a2ed19d2a85c8edd3ec2aef"); const ecjacobian ecjacobian::base( gfield("aa87ca22be8b05378eb1c71ef320ad746e1d3b628ba79b9859f741e082542a385502f25dbf55296c3a545e3872760ab7"), gfield("3617de4a96262c6f5d9e98bf9292dc29f8f41dbd289a147ce9da3113b5f0b8c00a60b1ce1d7e819d7a431d7c90ea0e5f") ); #elif GF_BITS==521 const gfield gfield::P("1ffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffff"); const gfield ecjacobian::B("051953eb968e1c9a1f929a21a0b68540eea2da725b99b315f3b8b489918ef109e156193951ec7e937b1652c0bd3bb1bf073573df883d2c34f1ef451fd46b503f00"); const ecjacobian ecjacobian::base( gfield("c6858e06b70404e9cd9e3ecb662395b4429c648139053fb521f828af606b4d3dbaa14b5e77efe75928fe1dc127a2ffa8de3348b3c1856a429bf97e7e31c2e5bd66"), gfield("11839296a789a3bc0045c8a5fb42c7d1bd998f54449579b446817afbd17273e662c97ee72995ef42640c550b9013fad0761353c7086a272c24088be94769fd16650") ); #else #error Unsupported GF #endif void calcpubkey(gfint privkey, vector &pubstr) { ecjacobian c(ecjacobian::base); c.mul(privkey); c.normalize(); c.print(pubstr); pubstr.add('\0'); } bool calcpubkey(const char *privstr, vector &pubstr) { if(!privstr[0]) return false; gfint privkey; privkey.parse(privstr); calcpubkey(privkey, pubstr); return true; } void genprivkey(const char *seed, vector &privstr, vector &pubstr) { tiger::hashval hash; tiger::hash((const uchar *)seed, (int)strlen(seed), hash); bigint<8*sizeof(hash.bytes)/BI_DIGIT_BITS> privkey; memcpy(privkey.digits, hash.bytes, sizeof(hash.bytes)); privkey.len = 8*sizeof(hash.bytes)/BI_DIGIT_BITS; privkey.shrink(); privkey.printdigits(privstr); privstr.add('\0'); calcpubkey(privkey, pubstr); } bool hashstring(const char *str, char *result, int maxlen) { tiger::hashval hv; if(maxlen < 2*(int)sizeof(hv.bytes) + 1) return false; tiger::hash((uchar *)str, strlen(str), hv); loopi(sizeof(hv.bytes)) { uchar c = hv.bytes[i]; *result++ = "0123456789abcdef"[c>>4]; *result++ = "0123456789abcdef"[c&0xF]; } *result = '\0'; return true; } void answerchallenge(const char *privstr, const char *challenge, vector &answerstr) { gfint privkey; privkey.parse(privstr); ecjacobian answer; answer.parse(challenge); answer.mul(privkey); answer.normalize(); answer.x.printdigits(answerstr); answerstr.add('\0'); } void *parsepubkey(const char *pubstr) { ecjacobian *pubkey = new ecjacobian; pubkey->parse(pubstr); return pubkey; } void freepubkey(void *pubkey) { delete (ecjacobian *)pubkey; } void *genchallenge(void *pubkey, const void *seed, int seedlen, vector &challengestr) { tiger::hashval hash; tiger::hash((const uchar *)seed, seedlen, hash); gfint challenge; memcpy(challenge.digits, hash.bytes, sizeof(hash.bytes)); challenge.len = 8*sizeof(hash.bytes)/BI_DIGIT_BITS; challenge.shrink(); ecjacobian answer(*(ecjacobian *)pubkey); answer.mul(challenge); answer.normalize(); ecjacobian secret(ecjacobian::base); secret.mul(challenge); secret.normalize(); secret.print(challengestr); challengestr.add('\0'); return new gfield(answer.x); } void freechallenge(void *answer) { delete (gfint *)answer; } bool checkchallenge(const char *answerstr, void *correct) { gfint answer(answerstr); return answer == *(gfint *)correct; }